Energy of a Tossed Ball

Page 1

Figure 1

When a body moves under the influence of gravity alone, its mechanical energy (the sum of its kinetic energy, KE, and potential energy, PE) is conserved. đ??žđ??¸ + đ?‘ƒđ??¸ = đ?‘?đ?‘œđ?‘›đ?‘ đ?‘Ąđ?‘Žđ?‘›đ?‘Ą

(1)

When a ball is tossed up in the air it begins with kinetic energy. As it rises it slows down, losing kinetic energy and gaining potential energy. On its way down, the ball loses potential energy but gains kinetic energy.

einstein™Tablet+ with MiLAB or Android/iOS Tablet with MiLAB and einstein™LabMate Distance sensor Distance adaptor 

Small stand



Clamp

Basketball or similar sized ball


1.

Measure and record the mass of the ball.

2.

Launch MiLAB (

3. 4. 5.

Connect the Distance sensor with the Distance adaptor to one of the ports on the einstein™LabMate. Assemble the equipment as shown in Figure 1. Make sure that only the Distance sensor is selected.

).

Program the sensor to log data according to the following setup: Distance Sensor

Distance (m)

Rate:

25/sec

Duration:

20 Sec

1.

Using two hands, practice tossing the ball straight up. The range should be from about 0.5 m above the Distance sensor to about 1.5 m above the Distance sensor.

2.

Tap Run (

3. 4.

When you hear the clicking sound of the Distance sensor, toss the ball and move your hands out of the way. Catch the ball when it is comes back to about 0.5 m above the Distance sensor.

5.

Tap Stop (

6.

Save the results by tapping Save (

) to begin recording data.

). ).

For more information on working with graphs see: Working with Graphs in MiLAB.

1.

Display a graph of the Velocity by taking the derivative of the distance vs time graph: a. Tap the Function button ( b. Tap the Setup button (

2.

). ) next to the Derivative function from the Mathematical Functions menu.

c. In the G1 drop down menu select the Distance data. d. The line which is drawn on the graph represents the velocity of the cart. Use the velocity data to calculate the kinetic energy of the ball: a. Tap the Function button ( b. Tap the Setup button (

). ) next to the Square function from the Mathematical Functions menu.


c. In the Math Functions window which opens, select the calculated velocity data from the G1 drop down menu. d. In the A edit box, enter half the value of the mass of the ball. e. Type KE in the Name edit box; type J in the Unit edit box.

1.

Use the cursor to select the Distance data: a. Tap the Function button ( b. Tap the Setup button (

). ) next to the Linear function from the Mathematical Functions menu.

c. In the Math Functions window which opens, select the Distance data from the G1 drop down menu. d. In the A edit box, enter the result of the mass of the ball multiplied by the free fall acceleration (9.8 m/s2). e. In the B edit box enter 0. f. Type PE in the Name edit box; type J in the Unit edit box.

1.

Export the data (

) as a .csv file.

2. Create a plot of Potential Energy vs Kinetic Energy. Discuss the graph in terms of the transitions between potential and kinetic energy and conservation of energy.


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